Device for absorbing water vapour

ABSTRACT

There is provided a container ( 2 ) for absorbing water vapour from ambient air, the container having an opening ( 8 ) to permit water vapour to enter the container, a perforate shelf ( 14 ) positioned above the base of the container and having a water-absorbing agent disposed thereon for absorbing water vapour, and an airway ( 26 ) which allows air to flow into the region of the container beneath the shelf, wherein the shelf comprises a non-planar surface on which the water-absorbing agent is disposed.

The present invention relates to a device for absorbing water vapour. Particularly, although not exclusively, it relates to a container for dehumidifying air in a confined or limited space; and to associated methods.

Humidity, or water vapour in air, is often undesirable as it may interfere with the storage of moisture sensitive materials, such as foodstuffs, cosmetics, pharmaceuticals, household goods and clothes, or it may adversely effect the operation of moisture sensitive equipment. This problem may be particularly pronounced in those areas where humidity levels are particularly high, such as those countries having hot humid climates.

It is therefore often desirable to dehumidify air. Traditional methods for dehumidifying air include the use of mechanical refrigeration equipment and water absorbent materials, such as silica gel.

Typically, methods employing refrigeration equipment involve cooling air to a predetermined temperature below its dew point, so that water condenses from the air and the water may be drained away. Thereafter, the air may be reheated to a predetermined warmer temperature. Techniques including absorbent materials may include continuous operation systems so that water is absorbed by the absorbent in a first cycle and then water desorbed from the absorbent by the application of heat in a second cycle.

Suitably, these techniques suffer from various disadvantages as they typically require bulky and heavy equipment, such as compressors, fans and heaters, which are interconnected by a network of pipes so that water vapour is absorbed continuously from air. Typically, such systems are ill-suited for operation in a confined or limited space. Moreover, the cost associated with such systems may prohibit their use in a domestic environment.

In an attempt to overcome the disadvantages associated with using the aforementioned systems in a confined or limited space, alternative techniques have been developed that include exposing air to an absorbent material. In particular, portable smaller devices comprising a container housing an absorbent material have been employed for dehumidifying air in a limited or confined space, particularly in a domestic environment.

Although absorbents such as silica gel may be employed in these devices, typically silica gel only absorbs up to 30% its weight of water and it is necessary to employ an absorbent having a higher capacity for water vapour absorption to prolong the life and improve the efficiency of the device. Suitably, hygroscopic deliquescent agents, such as calcium chloride, which may absorb 4 to 5 times its weight of water, have been employed in such devices. On absorption of water vapour the deliquescent agent dissolves to form a salt solution.

Although these devices have gone some way to solving the problems associated with absorbing water vapour in a confined space, particularly in a domestic environment, it would be desirable to have more efficient uptake of water vapour.

The present invention seeks to achieve the efficient absorption of water vapour, in particular, absorption of water vapour from air in a confined space, particularly in a domestic environment.

According to a first aspect the present invention provides a container for absorbing water vapour from ambient air, the container having an opening to permit water vapour to enter the container, a perforate shelf positioned above the base of the container and having a water-absorbing agent disposed thereon for absorbing water vapour, and an airway which allows air to flow into the region of the container beneath the shelf, wherein the shelf comprises a non-planar surface on which the water-absorbing agent is disposed.

The inclusion of a shelf having a non-planar surface on which the water-absorbing agent is disposed increases the effective surface area of the water-absorbing agent exposed to water vapour compared to the same quantity of water-absorbing agent placed on a shelf having a planar surface. Suitably, a water-absorbing agent in the container of the present invention may absorb water vapour more efficiently compared with the same quantity of water-absorbing agent in a comparable container including a planar shelf over an identical period of time. In addition such a construction may enable a user to see quickly that proper operation has commenced, because liquid may drip through the shelf from the water absorbing agent more readily than through a planar shelf.

Preferably, the water-absorbing agent is a deliquescent agent that forms a liquid on absorption of water vapour. Preferred deliquescent agents include calcium chloride and magnesium chloride as these not only exhibit an acceptable water absorption capacity but they are relatively non-caustic which render them suitable for use in devices that may be placed in a domestic environment. This does not exclude other deliquescent salts, for example when intended for use in other environments, for example industrial environments.

One preferred water-absorbing agent is calcium chloride alone. Another is magnesium chloride. Especially preferred is calcium chloride providing up to 20 wt % of the total content and the balance comprising a different water-absorbing agent, preferably magnesium chloride.

Suitably, when a deliquescent agent as defined above is used in the container of the present invention the non-planar surface of the shelf may promote improved drainage of liquid from the remaining deliquescent agent upon dissolution of the deliquescent agent. This may prohibit the remaining deliquescent agent from becoming coated with a barrier of liquid, and may thereby improve the water absorption capacity or efficiency of the deliquescent agent.

Suitably, the water-absorbing agent as defined above may include other components selected from a binder or thickener, for example starch, a pest control agent, a perfume, and odour absorbing agent (for example a zeolite), an antimicrobial agent, and combinations thereof. Preferably, when the water-absorbing agent comprises a deliquescent agent then an antimicrobial agent is included to prevent microbe formation in liquid formed by dissolution of the deliquescent agent.

Preferably, the non-planar surface extends over the entire shelf.

Preferably the shelf extends substantially between the side wall, or walls, of the container; except for the airway which allows air to flow between the regions above and below the shelf. The airway may conveniently be located at the periphery of the shelf, between the shelf and the wall of the container. Preferably the airway is formed at least in part by a wall portion which is in contact with the water-absorbing agent. When the airway is at the periphery of the sheet the airway is between that wall portion and the wall of the container. When the airway is not at the periphery of the sheet that wall portion entirely defines the airway, and is surrounded, in use, by the water-absorbing agent. Whichever variant is employed the wall portion is preferably also perforate, so that water vapour in the airway can flow from the airway to the water-absorbing agent, through the wall portion; or can flow into the region beneath the shelf. The region of the wall portion which is in contact with the water-absorbing agent is preferably non-planar, and preferred shapes described herein for the shelf also apply to this region of the wall portion of the airway.

Suitably there are two airways, preferably arranged opposite to one another.

According to a preferred embodiment of the present invention, the non-planar surface comprises a plurality of relief features, extending across a part of or the entire shelf. Preferably it has a repeating relief profile which extends over the entire shelf.

Preferably, the non-planar surface comprises a plurality of protrusions (within which term we include grooves or corrugations as well as individual projections or “blisters”) extending from the surface of the shelf. The plurality of protrusions may extend upwardly and/or downwardly from the surface of the shelf. Preferably, each of the plurality of protrusions extend in the same direction from the surface of the shelf. Most preferably, each of the plurality of protrusions upwardly extend from the surface of the shelf. Protrusions may suitably be conical or part-spherical. Preferably each protrusion is associated with a recess beneath it. The shelf is thus suitably a plastics moulded body.

Preferably, the non-planar surface comprises a planar surface area disposed between successive protrusions. In other words, a part or the entire surface of the shelf comprises adjacent protrusions separated by flat surface areas.

Alternatively, the non-planar surface comprises a plurality of protrusions wherein successive protrusions are immediately adjacent to one another. In other words, a part of or the entire surface of the shelf comprises adjacent protrusions, densely packed and not separated by flat surface areas.

Preferably, the plurality of protrusions on the surface of the shelf define a regular array. More preferably, the plurality of protrusions are in rows extending normally to the lengthwise and/or widthwise axis of the shelf.

It will be appreciated that a distance between peaks of two successive protrusions defines a pitch for the two protrusions. Suitably, the pitch between successive protrusions may vary across a part of or the entire surface of the shelf. Preferably, the pitch between successive protrusions is constant across a part of or the entire surface of the shelf. Most preferably, the pitch between protrusions is constant across the entire surface of the shelf.

Suitably, the protrusions may have a spherical, conical, frustoconical, cylindrical or prismatic shape. Such shapes are readily manufactured. In principle, however, other shapes including undercut shapes may be used. Preferably, all of the protrusions have the same shape. More preferably, all of the protrusions have a conical (including frusto-conical) shape.

Preferably, the surface area of the shelf used in the present invention is at least 10% more than the surface area of the corresponding planar shelf, preferably at least 20% more, most preferably at least 40% more.

The shelf is perforate, and so has one or more openings extending therethrough. These are distinct from the airway(s) mentioned above. The openings are intended to allow water to drip from the water-absorbing agent on the shelf.

Preferably, the one or more openings extend through the shelf and through one or more of the plurality of protrusions, when present.

The openings may be of any shape and of any size which allows for good passage of liquid, but retention of the water-absorbing material on the shelf. Suitable shapes include circles, squares and slits.

Typically, the openings as defined above have a minimum width of 0.1 mm to 2 mm.

Preferably, the container inlet is covered with a semi-permeable membrane to permit water vapour to enter the container and prevent liquid from exiting the container. Suitable semi-permeable membranes are well known to those skilled in the art, such as polytetrafluoroethylene (PTFE) membranes available from W L Gore and Associates Inc., or polyolefin films available under the trade mark TYVEK, or polyurethane films. The semi-permeable membrane not only permits the container of the present invention to function satisfactorily but also prevents spillage of liquid from the container formed by dissolution of the water-absorbing agent, when a deliquescent agent is used.

Preferably, the semi-permeable membrane is immovably secured across the inlet of the container to prevent a user accessing the interior of the container and contacting the water-absorbing agent, thereby improving the safety rating of the container.

Preferably, a semi-permeable membrane used in the present invention is of a type which provides moisture transmission of at least 1000 g, preferably at least 5000 g, and most preferably at least 10000 g water/m² membrane/day.

Suitably, the inlet of the container includes a removable fluid tight seal so that it may be stored without degradation of the water-absorbing agent. Suitably, the fluid tight seal extends across the semi-permeable membrane.

According to a further preferred embodiment, the container of the present invention further includes an indicator means for providing an indication of the status of the container. Suitably, the indicator means is responsive to the absorption of liquid by the water-absorbing agent.

The inclusion of an indicator means in the container of the present invention may indicate that the container is functioning satisfactorily and thus maintaining the environment in which the container is placed at an acceptable humidity level. Suitably, the indicator means indicate the end or prospective end of the useful life of the container. Consequently, the humidity level of an environment in which the container is placed may be maintained at a desired level by replacing the container at the end of its life. This may not only negate unnecessary increased expenditure by replacement of the container prior to the end of its useful life but also may avoid an undesirable increase in humidity in a specific area resulting from replacement of the container after expiration of its useful lifetime.

Preferably, the indicator means is separate from the water-absorbing agent.

By the term “separate” we include that the indicator means is an entity separate from the water-absorbing agent. In other words, the water-absorbing agent is not coated or impregnated with the indicator means.

Suitably, an indicator means separate from the water-absorbing agent, particularly an indicator means that is responsive to liquid formed by dissolution of a deliquescent agent, may provide an indication of the amount of liquid produced by the water-absorbing agent. Suitably the arrangement is such that the indicator means operates when the liquid has reached a predetermined level. Preferably the indicator means is located in the region of the container above the shelf.

According to one possible embodiment of the present invention, the indicator means provides a continuous indication of the amount of water vapour absorbed by the water-absorbing agent. Suitably, this may provide an indication that the container is functioning satisfactorily, for example by assessing whether the moisture content of the environment in which it is placed is being maintained at an acceptable level.

Alternatively, or additionally, the indicator means may provide an indication that the container has reached the end of its useful life and needs to be replaced and/or the container is about to reach the end of its useful life and will need to be replaced shortly.

Preferably, the indicator means provides a visible and/or audible signal that is indicative of the status of the container.

Typically, it is possible to arrange and/or calibrate the indicator means so that it either provides a continuous indication of the amount of water vapour absorbed by the water-absorbing agent and/or it indicates when the device has come to or, preferably, is about to come to the end of its useful life. Suitably, where the indicator means is responsive to liquid formed by dissolution of the water-absorbing agent upon absorption of water vapour, this may be achieved by measuring the level and location of liquid formed in a particular container following absorption of specific amounts of water vapour by specific quantities of a particular deliquescent agent placed in the container. Consequently, it is possible to arrange the indicator means in the container so that it responds to a specific level or specific levels of liquid in the container corresponding to a specific amount of water vapour absorbed by a known amount of deliquescent agent.

According to a preferred embodiment of the present invention, the indicator means comprises a colorant.

Preferably, the colorant is a dye is miscible with the liquid formed by dissolution of the deliquescent agent so that it provides an instantaneous visible signal of the amount of water vapour absorbed by the water-absorbing agent.

Preferably, the dye is formulated into a formulation that dissolves on contact with liquid formed by dissolution of the deliquescent agent. For example, the dye may be in the form of a capsule, tablet or encased in a liquid soluble pouch or sachet.

Preferably, the dye is arranged within the container so that it mixes with liquid only when a specific amount of the salt solution has dissolved in the container. Suitably, the dye is arranged in the container so that it is contacted by the liquid when the container has reached or is about to reach the end of its useful life.

Preferably, the dye as defined above is attached to an inner wall of the container or placed on a platform in the container. In either case it is preferably held in the region of the container above the shelf, suitably in the upper half of that region. Location of the dye in a central position of the container, for example on a platform supported by the shelf, has the advantage in that false signals due to tilting are less likely.

It will be appreciated from the above that when the indicator means comprises a colorant, then the indicator means generates a visible signal that is representative of the status of the device of the present invention e.g. the container has reached or is about to reach the end of its useful life. Moreover, if the colorant is a dye miscible with the liquid then a near instantaneous signal is provided when the dye mixes with the liquid.

According to a further preferred embodiment of the present invention, the indicator means comprises a plurality of electrodes arranged to be in electrical communication with each other and a signalling device, whereby upon formation of salt solution due to absorption of water vapour by a deliquescent water-absorbing agent an electrical potential is generated which operates the signalling device thereby providing an indication of the amount of water vapour absorbed by the water-absorbing agent.

Suitably, the dissolution of the deliquescent agent as defined hereinbefore produces an electrolyte comprising an aqueous solution of a water-soluble salt, such as an aqueous calcium chloride and/or magnesium chloride solution. Contact of the electrolyte by the plurality of electrodes forms an electrochemical cell and an electrical potential is generated across the electrodes which permits a current to flow through and power the signalling device.

The plurality of electrodes may take any conventional form and be constructed from any conventional material for an electrochemical cell. The electrodes may comprise a pair of rod members having the desired electrical characteristics. Alternatively, one or more of the plurality of electrodes may form the inner surface of the container. As will be appreciated by those skilled in the art, it is necessary for the plurality of electrodes to have distinct and different electronegativities in order to generate an electrical potential to form an electrochemical cell. The electrodes may be constructed, for example, from zinc, copper, carbon or aluminium. The container may also include conventional antidepolarisation and/or anti-plating agents which inhibit depolarisation of the electrochemical cell and/or plating of the plurality of electrodes respectively.

Suitably, the plurality of electrodes may be arranged so that contact between the electrodes and the electrolyte formed by dissolution of the deliquescent agent occurs only after a specific amount of the deliquescent agent has dissolved e.g. contact occurs at or near the end of the useful life of the device of the present invention.

The signalling device which is in electrical communication with the plurality of electrodes may generate an audible signal, such as an alarm. Alternatively or additionally, the signalling device may comprise a visual signalling means, such as a light, an array of lights, or an LED display. An array of different coloured lights or an LED display is particularly preferred for providing a continuous indication of the amount of water vapour absorbed by the water-absorbing agent with time. For example, a series of green, amber and red coloured lights may be employed: the green light being lit to indicate the device is operating satisfactorily and it does not need replacing; the amber light being lit to indicate the device is operating satisfactorily but it is approaching the end of its useful life and will need replacing with a new one shortly; and the red light being lit to indicate the device has reached the end of its useful life and needs replacing immediately with a new one.

It will be appreciated that a battery-aided indicator means may be provided; the electrochemical potential alone may not be sufficient in some embodiments to power the circuitry or signalling devices which are employed.

Preferably, the container further includes an outlet having a resealable fluid tight seal to permit drainage of liquid from the container and/or to permit water-absorbing agent to be added to the container. Conveniently, this enables the container of the present invention to be re-used thereby decreasing the amount of expenditure required when it is necessary to replace an exhausted device with a new one.

Suitably, the container of the present invention is dimensioned so that it may be used in a confined space, particularly a confined space in a domestic environment, such as a drawer, chest, wardrobe, cupboard, packing case, refrigerator, freezer, cool box, caravan, car, car boot or boat. Suitably, the container of the present invention is 5 to 30 cm high, 10 to 50 cm long, and 5 to 30 cm wide. Typically, the device includes 50-1000 g of water-absorbing agent, preferably 100-500 g.

Suitably, the container is rigid or flexible. Most preferably, the container is rigid.

Preferably, the container, including the shelf and airway, are formed from a plastics material, for example a polyolefin, by techniques well known to those skilled in the art such as injection moulding, blow moulding and vacuum forming.

According to a further aspect, the present invention provides a method for removing water vapour from air, comprising providing a container as described hereinbefore and placing the container in a humid atmosphere. Preferably, the container is placed in a confined space.

According to a further aspect, the present invention provides the use of a shelf as described hereinbefore for increasing the effective external surface area of a body of a water-absorbing agent as defined hereinbefore, for enhanced exposure to water vapour.

According to a further aspect, the present invention provides the use of a shelf as described hereinbefore for increasing the capacity of a water-absorbing agent as defined hereinbefore to absorb water vapour.

The present invention will now be illustrated by way of the following non-limiting examples, in which:

FIG. 1 is a perspective view of a container of the present invention;

FIG. 2 is a perspective view of a shelf of an alternative container of the present invention;

FIG. 3 is a perspective view of a further shelf;

FIG. 4 is a perspective view of an alternative container of the present invention, including a dye as indicator means; and

FIG. 5 is a perspective view of an alternative container of the present invention including an electrochemical cell as indicator means.

FIG. 1 shows a rigid plastics container (2) of translucent HDPE material. In FIG. 1 solid lines denote features of unobstructed view and dotted lines denote features visible hazily through the translucent HDPE.

The container of FIG. 1 is formed by injection moulding, and has a lozenge-shaped or parallel-sided oval-shaped base (4) and a side wall (6) extending upwardly from base (4) to define an opening (8) at its upper end. The upper end of side wall (6) terminates in an annular rim (10) that extends around the opening (8). A semi-permeable membrane (not shown) comprised of TYVEK material (Trade Mark; HDPE material, from Du Pont) is heat sealed to rim (10) so that it extends across and covers the opening (8). The interior of the container (2) includes a plastics shelf of translucent HDPE (14) supported by supports (16), being upright ribs moulded on the internal surface of the side wall. The shelf (14) has a plurality of upstanding conically shaped projections (18) of height 3 cm extending upwardly from the shelf. The nature of these projections is most clearly apparent from FIGS. 2 and 3, showing similar shelves. A plurality of circular holes (not shown) of diameter 1 mm pass through the shelf (14), both through the plurality of conical shaped projections (18) and the planar web between them. The shelf supports a calcium chloride water-absorbing agent (not shown) which covers the conical projections (18). The wall (6) of container (2) includes at opposite ends airways or vents (26). Each airway extends upwardly from the shelf, to near the top of the container, and has a surface (28) spaced from the wall. There is a space between the surface (28) and the wall. The surfaces (28) of the airways are co-moulded with the shelf. Each surface (28) is perforate, having an array of parallel slits extending from the top to the bottom of the surface. When the water-absorbing agent is on the shelf air may reach the region of the container beneath the shelf, and thence the under-surface of the body of water-absorbing agent. To do this air entering the container through opening (8) can pass through the slits, whose top regions are not covered by the body of water-absorbing agent. The air is then in the airway and can flow downwards. Where it passes the shelf it is not impeded; the airway is unoccluded throughout its length.

In this embodiment the surface (28) of each airway has a somewhat convex shape, to follow the shape of the container, but is not formed with conical projections or any other substantial relief profile. However in other embodiments it can be so, and this is a further, albeit smaller, way in which the effective external surface area of the body of water-absorbing agent can be increased.

The operation of the container shown in FIG. 1 is simple. After purchase the user removes an impermeable plastics cover (not shown). This is provided during manufacture in order to maintain the water-absorbing material in a substantially desiccated condition, prior to the commencement of use. The opening remains covered by the membrane. The user places the container on a level surface in an air space in which reduction of humidity is desired. Whenever water vapour can come into contact with the body of water-absorbing agent there is the prospect that water molecules will be absorbed. Water molecules can be absorbed at the exposed upper surface of the body of water-absorbing material, at its under-surface, and through the airways. The latter two possibilities arise because air can flow through the airways into the region of the container beneath the shelf. The absorption of water vapour is considerably improved by the provision of the specially shaped shelf. The topography of the shelf not only increases the effective surface area of the body of the water-absorbing area but also promotes the free drainage of aqueous calcium chloride solution.

FIG. 2 is a perspective view of a shelf similar to that of FIG. 1. The main differences are that it is elliptical and that it is not co-moulded with surfaces (28) of the airways. The airways (not shown) are wholly moulded as part of the container wall. The elliptical shelf (14) may be seen as having upper (29) and lower (30) surfaces. The upper surface (29) comprises an array of upstanding conical shaped projections (18) having a height of 3 cm. The base of each conically shaped projection (18) has a radius of 1 cm, the height of each is 3 cm and the pitch between successive projections is 2 cm. The projections (18) are arranged in rows that are perpendicular to the lengthwise axis of the shelf (14) and successive projections (18) are separated by flat areas (32) on the upper surface (29) of the shelf (14). A multiplicity of small circular openings (not shown) pass through the shelf (14) and the plurality of conical shaped projections (18).

FIG. 3 is a perspective view of an arrangement similar to that of FIG. 2, but wherein the shelf is rectangular FIG. 4 shows the device of FIG. 1 further including a dye as an indicator means where corresponding parts have been identified with identical reference numerals. In FIG. 4, a food coloring dye, (for example one of the SANDOLAN (Trade mark) available from Clariant, Leeds, UK or any food coloring dye) in a small water soluble sachet (40), (for example employing a PVOH-, starch-, sugar-, or gelatin-based material), having the appearance of a bead or button and adhered to the side wall (6) of container (2) at a predetermined position in the region of the container above the shelf, corresponding to the level of liquid formed when the container is exhausted, and should be replaced.

As mentioned above, following absorption of water vapour by the deliquescent agent, an aqueous calcium chloride solution drains from the residual deliquescent agent onto the base (4) of the container (2). The level of aqueous calcium chloride solution rises within the container (2) as more deliquescent agent absorbs water vapour and dissolves. Presently the aqueous calcium chloride solution in the container (2) reaches the same level as the water soluble sachet (40). The aqueous calcium chloride solution dissolves the sachet (40) and the dye contained therein dissolves in the calcium chloride solution, thereby providing an instantaneous visual indication that device has reached, or almost reached, the end of its useful life.

FIG. 5 shows an alternative embodiment of the device as illustrated in FIG. 4 and corresponding features are indicated with identical reference numerals. In the device of FIG. 5, zinc (50) and a copper (52) electrode rods extend from a predetermined level, corresponding to the level of liquid formed when the amount of water vapour absorbed by the container is at its maximum value, through shelf (14) and to the base (4) of the container (2). The electrodes (50,52) are spaced apart from each other and are connected in electrical communication with red, amber and green LEDs (54,56,58) by electrically conducting leads (60,62) and a small switching circuit (64). LEDs (54,56,58) independently produce green, amber and red light, respectively, when they are lit.

In use water passes through the semi-permeable membrane (12) and contacts the deliquescent agent which upon absorption of water vapour forms an electrolyte comprising an aqueous calcium chloride solution. The aqueous calcium chloride solution drains from the deliquescent agent, via the openings (22) in the shelf (14) and to a small degree the airways (26) into the base (4) of the container (2) where it contacts the two electrodes (50,52). An electric potential is generated by the two electrodes and an electric current flows between the electrodes (50,52) via conducting leads (60,62) and light (54) which produces a green light indicating the device is operating satisfactorily and it does not need replacing. The resistance of the electrical circuit comprising the two electrodes (50,52), lights (54,56,58) and electrical conducting leads (60,62) is such that the ionic concentration of the calcium chloride electrolyte increases with further dissolution of the deliquescent agent. When the ionic strength of the electrolyte has reached a value indicative of the fact that the container is at the end of its useful life, the amber light (56) is illuminated and green light turned off. When the strength of the electrolyte reaches a peak value indicating that the amount of water vapour absorbed by the device is at its maximum value, the red light is illuminated and the amber light turned off, thereby indicating that the container has reached the end of its useful life and needs replacing.

In an alternative embodiment the determination is not achieved by ionic strength of the electrolyte, but simply by the circuitry “recognising” the immersion in electrolyte of electrodes in succession; notionally, of a “green electrode”, then an “amber electrode” and finally a “red electrode”. 

1. A container for absorbing water vapour from ambient air, the container having an opening to permit water vapour to enter the container, a perforate shelf positioned above the base of the container and having a water-absorbing agent disposed thereon for absorbing water vapour, and an airway which is unoccluded throughout its length and which allows air to flow into the region of the container beneath the shelf, wherein the shelf comprises a non-planar surface on which the water-absorbing agent is disposed.
 2. A container according to claim 1 wherein the water-absorbing agent is a deliquescent agent.
 3. A container according to claim 1 wherein the non-planar surface contacting the water-absorbing agent has a repeating relief profile or motif which extends over the entire shelf.
 4. A container according to claim 1 wherein the non-planar surface comprises a plurality of protrusions extending from the surface of the shelf.
 5. A container according to claim 4 wherein the plurality of protrusions comprise spherical, conical, frustoconical, cylindrical and/or prismatic shaped protrusions extending from the surface of the shelf.
 6. A container according to claim 4 wherein the perforations in the shelf extend through the shelf and the one or more plurality of protrusions.
 7. A container according to claim 1 wherein the opening of the container is covered by a semi-permeable membrane.
 8. A container according to claim 1 further including indicator means for providing an indication of amount of water vapour absorbed the water-absorbing agent.
 9. A container according to claim 1 wherein the water-absorbing agent comprises calcium chloride.
 10. A method of dehumidifying an air space, comprising the placement in the air space of a container according to claim
 1. 11. Use of a shelf for increasing the effective external surface area of a body of a water-absorbing agent for enhanced exposure to water vapour, wherein at least a part of the shelf comprises a non-planar surface for contacting the water-absorbing agent.
 12. Use of a shelf for increasing the capacity of a water-absorbing agent to absorb water vapour, wherein at least a part of the shelf comprises a non-planar surface for contacting the water-absorbing agent.
 13. (canceled)
 14. (canceled) 